Which of the following techniques is the best option for dividing an integer by 2 and why?
Technique 1:
x = x >> 1;
Technique 2:
x = x / 2;
Here x
is an integer.
Use the operation that best describes what you are trying to do.
Note that they are not exactly equivalent. They can give different results for negative integers. For example:
-5 / 2 = -2
-5 >> 1 = -3
%
and /
operators must be consistent for both positive and negative operands so that (a/b)*b+(a%b)==a
is true regardless of the signs of a
and b
. Usually, the author will make choices that get the best possible performance out of the CPU.
Does the first one look like dividing? No. If you want to divide, use x / 2
. Compiler can optimise it to use bit-shift if possible (it's called strength reduction), which makes it a useless micro-optimisation if you do it on your own.
To pile on: there are so many reasons to favor using x = x / 2;
Here are some:
it expresses your intent more clearly (assuming you're not dealing with bit twiddling register bits or something)
the compiler will reduce this to a shift operation anyway
even if the compiler didn't reduce it and chose a slower operation than the shift, the likelihood that this ends up affecting your program's performance in a measurable way is itself vanishingly small (and if it does affect it measurably, then you have an actual reason to use a shift)
if the division is going to be part of a larger expression, you're more likely to get the precedence right if you use the division operator:
x = x / 2 + 5;
x = x >> 1 + 5; // not the same as above
signed arithmetic might complicate things even more than the precedence problem mentioned above
to reiterate - the compiler will already do this for you anyway. In fact, it'll convert division by a constant to a series of shifts, adds, and multiplies for all sorts of numbers, not just powers of two. See this question for links to even more information about this.
In short, you buy nothing by coding a shift when you really mean to multiply or divide, except maybe an increased possibility of introducing a bug. It's been a lifetime since compilers weren't smart enough to optimize this kind of thing to a shift when appropriate.
a/b/c*d
(where a..d
denoted numeric variables) instead of the far more readable (a*d)/(b*c)
.
a*d
or b*c
would produce an overflow, the less readable form is not equivalent and has an obvious advantage. P.S. I agree that parentheses are your best friend.
Commented
Jun 8, 2012 at 16:36
a/b/c*d
in R code--in a context where overflow would mean that something was seriously wrong with the data--and not in, say, a performance-critical block of C code).
x=x/2;
is only "clearer" than x>>=1
if x
will never be an odd negative number or one doesn't care about off-by-one errors. Otherwise x=x/2;
and x>>=1;
have different meanings. If what one needs is the value computed by x>>=1
, I would regard that as clearer than x = (x & ~1)/2
or x = (x < 0) ? (x-1)/2 : x/2
, or any other formulation I can think of using division by two. Likewise if one needs the value computed by x/=2
, that is clearer than ((x + ((unsigned)x>>31)>>1)
.
Which one is the best option and why for dividing the integer number by 2?
Depends on what you mean by best.
If you want your colleagues to hate you, or to make your code hard to read, I'd definitely go with the first option.
If you want to divide a number by 2, go with the second one.
The two are not equivalent, they don't behave the same if the number is negative or inside larger expressions - bitshift has lower precedence than +
or -
, division has higher precedence.
You should write your code to express what its intent is. If performance is your concern, don't worry, the optimizer does a good job at these sort of micro-optimizations.
Just use divide (/
), presuming it is clearer. The compiler will optimize accordingly.
ASSUME(x >= 0); x /= 2;
over x >>= 1;
, but that is still an important point to bring up.
Commented
Nov 2, 2013 at 1:17
I agree with other answers that you should favor x / 2
because its intent is clearer, and the compiler should optimize it for you.
However, another reason for preferring x / 2
over x >> 1
is that the behavior of >>
is implementation-dependent if x
is a signed int
and is negative.
From section 6.5.7, bullet 5 of the ISO C99 standard:
The result of
E1 >> E2
isE1
right-shiftedE2
bit positions. IfE1
has an unsigned type or ifE1
has a signed type and a nonnegative value, the value of the result is the integral part of the quotient ofE1
/ 2^{E2}. IfE1
has a signed type and a negative value, the resulting value is implementation-defined.
x>>scalepower
on negative numbers will be precisely what is needed when dividing a value by a power of two for purposes such as screen rendering, while using x/scalefactor
will be wrong unless one applies corrections to negative values.
>>
on signed integral types as an arithmetic right shift, i.e. shifting in copies of the sign bit for 2's complement. (e.g. GNU C guarantees that: gcc.gnu.org/onlinedocs/gcc/Integers-implementation.html.) Of course a Deathstation 9000 could do something non-useful, but this is not really a significant portability concern for most code. ISO C++ is even moving in the direction of standardizing it as an arithmetic right shift.
Commented
May 3, 2022 at 2:51
x / 2
is clearer, and x >> 1
is not much faster (according to a micro-benchmark, about 30% faster for a Java JVM). As others have noted, for negative numbers the rounding is slightly different, so you have to consider this when you want to process negative numbers. Some compilers may automatically convert x / 2
to x >> 1
if they know the number can not be negative (even thought I could not verify this).
Even x / 2
may not use the (slow) division CPU instruction, because some shortcuts are possible, but it is still slower than x >> 1
.
(This is a C / C++ question, other programming languages have more operators. For Java there is also the unsigned right shift, x >>> 1
, which is again different. It allows to correctly calculate the mean (average) value of two values, so that (a + b) >>> 1
will return the mean value even for very large values of a
and b
. This is required for example for binary search if the array indices can get very large. There was a bug in many versions of binary search, because they used (a + b) / 2
to calculate the average. This doesn't work correctly. The correct solution is to use (a + b) >>> 1
instead.)
x/2
to x>>1
in cases where x
may be negative. If what one wants is the value which x>>1
would compute, that will almost certainly be faster than any expression involving x/2
which computes the same value.
x/2
to x>>1
if he knows the value is not negative. I will try to update my answer.
Commented
Nov 2, 2013 at 7:40
div
instruction though, by converting x/2
into (x + (x<0?1:0)) >> 1
(where >> is an arithmetic right-shift, that shifts in sign bits). This takes 4 instructions: copy the value, shr(to get just the sign bit in a reg), add, sar. goo.gl/4F8Ms4
Commented
Oct 4, 2015 at 14:48
Knuth said:
Premature optimization is the root of all evil.
So I suggest to use x /= 2;
This way the code is easy to understand and also I think that the optimization of this operation in that form, don't mean a big difference for the processor.
(n+8)>>4
works nicely. Can you offer any approach which is as clear or as efficient without using a signed right shift?
Take a look at the compiler output to help you decide. I ran this test on x86-64 with
gcc (GCC) 4.2.1 20070719 [FreeBSD]
Also see compiler outputs online at godbolt.
What you see is the compiler does use a sarl
(arithmetic right-shift) instruction in both cases, so it does recognize the similarity between the two expressions. If you use the divide, the compiler also needs to adjust for negative numbers. To do that it shifts the sign bit down to the lowest order bit, and adds that to the result. This fixes the off-by-one issue when shifting negative numbers, compared to what a divide would do.
Since the divide case does 2 shifts, while the explicit shift case only does one, we can now explain some of the performance differences measured by other answers here.
C code with assembly output:
For divide, your input would be
int div2signed(int a) {
return a / 2;
}
and this compiles to
movl %edi, %eax
shrl $31, %eax # (unsigned)x >> 31
addl %edi, %eax # tmp = x + (x<0)
sarl %eax # (x + 0 or 1) >> 1 arithmetic right shift
ret
similarly for shift
int shr2signed(int a) {
return a >> 1;
}
with output:
sarl %edi
movl %edi, %eax
ret
Other ISAs can do this about as efficiently, if not moreso. For example GCC for AArch64 uses:
add w0, w0, w0, lsr 31 // x += (unsigned)x>>31
asr w0, w0, 1 // x >>= 1
ret
d
. Such partitioning is useful for many purposes. Even if one would rather have the breakpoint somewhere other than between 0 and -1, adding an offset will move it. An integer division which satisfies the second axiom will partition the number line into regions which are mostly of size d
, but one of which is of size 2*d-1
. Not exactly "equal" divisions. Can you offer suggestions of when the oddball partition is actually useful?
sar
). goo.gl/KRgIkb. This mailing list post (gcc.gnu.org/ml/gcc/2000-04/msg00152.html) confirms that gcc historically uses arithmetic shifts for signed ints, so it's highly unlikely that FreeBSD gcc 4.2.1 used unsigned shift. I updated your post to fix that and the early paragraph saying both used shr, when it's actually SAR that they both use. The SHR is how it extracts the sign bit for the /
case. Also included a godbolt link.
Commented
Oct 4, 2015 at 15:14
Just an added note -
x *= 0.5 will often be faster in some VM-based languages -- notably actionscript, as the variable won't have to be checked for divide by 0.
eval
) made that happen afresh each time. Regardless, yes, it is a pretty bad test, because it’s a very silly optimization.
I am telling for the purpose of programming competitions. Generally they have very large inputs where division by 2 takes place many times and its known that input is positive or negative.
x>>1 will be better than x/2. I checked on ideone.com by running a program where more than 10^10 division by 2 operations took place. x/2 took nearly 5.5s whereas x>>1 took nearly 2.6s for same program.
x/2
to x>>1
. For signed values, nearly all implementations define x>>1
to have a meaning which is is equivalent to x/2
but can be computed faster when x
is positive, and is usefully different from x/2
when x
is negative.
I would say there are several things to consider.
Bitshift should be faster, as no special computation is really needed to shift the bits, however as pointed out, there are potential issues with negative numbers. If you are ensured to have positive numbers, and are looking for speed then I would recommend bitshift.
The division operator is very easy for humans to read. So if you are looking for code readability, you could use this. Note that the field of compiler optimization has come a long way, so making code easy to read and understand is good practice.
If you are after pure performance, I would recommend creating some tests that could do the operations millions of times. Sample the execution several times (your sample size) to determine which one is statistically best with your OS/Hardware/Compiler/Code.
>>
does and doesn't match what /
does.
As far as the CPU is concerned, bit-shift operations are faster than division operations.
However, the compiler knows this and will optimize appropriately to the extent that it can,
so you can code in the way that makes the most sense and rest easy knowing that your code is
running efficiently. But remember that an unsigned int
can (in some cases) be optimized better than an int
for reasons previously pointed out.
If you don't need signed arithmatic, then don't include the sign bit.
Use x = x / 2;
OR x /= 2;
Because it is possible that a new programmer works on it in future. So it will be easier for him to find out what is going on in the line of code. Everyone may not be aware of such optimizations.
x = x / 2; is the suitable code to use.. but an operation depend on your own program of how the output you wanted to produce.
Make your intentions clearer...for example, if you want to divide, use x / 2, and let the compiler optimize it to shift operator (or anything else).
Today's processors won't let these optimizations have any impact on the performance of your programs.
The answer to this will depend on the environment you're working under.
x /= 2
into x >>= 1
, the presence of a division symbol will raise more eyebrows in that environment than using a shift to effect a division.x >>= 1
with a comment explaining its reasoning is probably best just for clarity of purpose.x /= 2
. Better to save the next programmer who happens to look at your code the 10 second double-take on your shift operation than to needlessly prove you knew the shift was more efficient sans compiler optimization.All these assume unsigned integers. The simple shift is probably not what you want for signed. Also, DanielH brings up a good point about using x *= 0.5
for certain languages like ActionScript.
generaly the right shift divides :
q = i >> n; is the same as: q = i / 2**n;
this is sometimes used to speed up programs at the cost of clarity. I don't think you should do it . The compiler is smart enough to perform the speedup automatically. This means that putting in a shift gains you nothing at the expense of clarity.
Take a look at this page from Practical C++ Programming.
(x+128)>>8
would compute for values of x
not near the maximum, how could one concisely do it without a shift? Note that (x+128)/256
won't work. Do you know of any nice expression that will?
Obviously, if you are writing your code for the next guy who reads it, go for the clarity of "x/2".
However, if speed is your goal, try it both ways and time the results. A few months ago I worked on a bitmap convolution routine which involved stepping through an array of integers and dividing each element by 2. I did all kinds of things to optimize it including the old trick of substituting "x>>1" for "x/2".
When I actually timed both ways I discovered to my surprise that x/2 was faster than x>>1
This was using Microsoft VS2008 C++ with the default optimizations turned on.
In terms of performance. CPU's shift operations are significantly faster than divide op-codes. So dividing by two or multiplying by 2 etc all benefit from shift operations.
As to the look and feel. As engineers when did we become so attached to cosmetics that even beautiful ladies don't use! :)
X/Y is a correct one...and " >> " shifting operator..if we want two divide a integer we can use (/) dividend operator. shift operator is used to shift the bits..
x=x/2; x/=2; we can use like this..
x
again, neither is appropriate in this way: it should be eitherx >>= 1
orx /= 2
, depending on what you intend to express with the operation. Not because it's faster (any modern compiler will compile all the equivalent variants to identical, fast assembly anyway) but because it's less confusing.x = x >>> 1
. Also note that depending on the platform and compiler it may be quite reasonable to manually optimize divisions and multiplications using shifts. - Thinking of micro controllers, for instance, w/o direct ALU support for multiplication.x /= 2
becausex >>= 1
looks too much like monadic bind ;)x = x / 2
instead ofx /= 2
. Subjective preference maybe :)⬜=
combinations, these should be used whenever it's possible. It removes noise and puts emphasis on the fact thatx
is modified, while the general=
operator rather suggests that it takes on a completely new value independent of the old one. — Always avoiding the combined operators (so that it's readable so someone who only knows mathematical operators) may have its point as well, but then you'd need to relinquish the extremely useful++
,--
,+=
, too.